REPORT: Silicon Chip Used By Israeli Team to Deliver Alzheimer’s-busting Protein to the Brain

If you’ve followed us here on this page for very long, you know that much of the time we bring you news with an emphasis on the political goings-on in Washington, D.C. as well as around the country, and in some cases, around the world.

We’re functioning as a modern-day version of what the Bible calls a “watchman on the wall.” We see what kind of garbage the Fake News is throwing at President Trump and this administration, and we’re doing our best to keep you informed of the lies and manipulations coming from the Left that have only one mission: to destroy the Republic of the United States of America and usher in a socialist global entity.

However, there are other newsworthy things that come to our attention, and this report today is one that we hope will spark some hope that progress is being made towards something that will improve the quality of life.

Researchers at the Technion–Israel Institute of Technology and Bar-Ilan University have developed technology they hope will help inhibit the progression of Alzheimer’s disease.

The study was published recently as a cover story in the journal Small. It was led by Prof. Ester Segal and PhD student Michal Rosenberg from the Technion Faculty of Biotechnology and Food Engineering with their partners, Prof. Orit Shefi and PhD student Neta Zilony-Hanin from the Bar-Ilan University Faculty of Engineering.

Alzheimer’s, the most common form of dementia, is a neurodegenerative disease whose symptoms include memory loss, speech impairment, orientation problems, and significant impairment of motor functions.

It primarily strikes the elderly, and among those age 85 and up it reaches a prevalence of some 30%. Due to the increase in life expectancy, the overall incidence of the disease has grown and it is today referred to as the epidemic of the 21st century.

The major cause of the disease is the accumulation of a protein called amyloid beta (Aβ) in brain tissues. The protein blocks and kills nerve cells, also called neurons, in different regions of the brain. This leads, in part, to damage of the “cholinergic mechanisms,” the neurons in charge of brain function.

Research has previously shown that administering a specific protein, called “neural growth factor,” inhibits damage to the cholinergic mechanisms and slows the disease’s progression, said the Technion’s Prof. Segal in a phone interview.

“In people with neurodegenerative diseases, the expression of the neural growth factor protein is reduced,” she said.

The protein is known to have restorative qualities, but the problem is how to get it to the brain, she said.

Delivering the protein to the target area is not a simple task because the brain is shielded by the blood-brain barrier from infiltration by bacteria and harmful substances in the blood.

This protective barrier, however, also restricts the passage of drugs from the bloodstream to the brain, making it difficult for brain-curing medications to get through.

Thus, the neural growth factor proteins, if given in drug form, do not pass through the barrier, and even if they could, they would not live long enough to make the long journey to the brain, Segal said.

Some clinical trials have already started injecting these neural growth factor proteins directly into the brain via a catheter, but the procedure is complicated, invasive and very risky, Segal said.

Now, the Technion and Bar-Ilan University researchers say they have created nanoscale silicon chips that could meet this challenge.

The chips allow the insertion of the curative protein directly into the brain and its release at the targeted tissue.

These chips, developed in Segal’s lab, have a nanoscale porous structure that allows them to be loaded with large amounts of the protein. Through precise control of various features, including the dimension of the chips’ pores and the chemical properties of their surface, the researchers were able to create a silicone structure that retains the protein in its active form and then releases it gradually, over a period of about a month, to the target area in the brain. After releasing the drug, the chips safely degrade in the brain and dissolve, the Technion said in a statement.

With the use of the chips as a vehicle, the protein no longer needs to cross the blood-brain barrier, since the chip is inserted directly into the brain. This is done in one of two possible ways, explained Segal.

The first is by implanting the chip into the brain. Segal admits that this procedure is also invasive, as the skull needs to be drilled into. But, she said, it is less invasive than inserting a catheter, since the chip is not inserted into the brain itself but rather is placed on the outer layer of the brain — the dura mater, a dense connective tissue that surrounds the brain and spinal cord. The researchers aim to eventually be able to load the chip with medication that releases even more gradually, over the period of a year, to prolong the drug’s effect. Currently, in trials with mice, the chip releases the proteins over a period of a month.

The second way to get the proteins to the brain is by using a “gene gun” — a device that has been developed to inject DNA into plant cells in order to transform their genetic structure.

As part of the study, Prof. Shefi of Bar-Ilan reworked the gun, transforming it into “something like a nose spray” that injects the silicon chip with the protein particles into the brain via the nose, bypassing the blood-brain barrier.

The nose has direct pathways to the brain, explained Segal “Not for nothing drug addicts sniff cocaine via their noses,” she said.

This is the first time researchers have successfully used a gene gun to directly deliver particles into a live animal brain, she said.

In a series of experiments, the researchers showed that the two ways of delivering the platform into mice brains “led to the desired result,” said Technion doctoral student Michal Rosenberg. The technology has also been tested on a cellular model of Alzheimer’s disease, where the protein release led to the rescue of the nerve cells, she said.

The team is already conducting pre-clinical studies on animals, at Bar-Ilan, Segal explained, and hopes to expand them to clinical trials if all goes as hoped.

The research was conducted with the support of the Russel Berrie Nanotechnology Institute at the Technion.